Abstract
High-fluence-rate white light is shown to retard the degradation of phytochrome in etiolated seedlings of four different species: Amaranthus caudatus, Phaseolus radiatus (mung bean), Pisum sativum (garden pea), and Avena sativa (oat). In Amaranthus, a high photon fluence rate (approx. 1000 μmol · m-2 · s-1) preserved nearly 50% of the total phytochrome over a period of 5 h; at 3 μmol · m-2 · s-1, less than 8% remained over the same period. Kinetics of the loss of total phytochrome could be interpreted in terms of two populations, one with rapid, and one with slow, turnover rates. A log-linear relationship between fluence rate and proportion of slowly degrading phytochrome was observed; a similar relationship between fluence rate and the amount of phytochrome remaining after a 5-h light treatment was seen. In mung bean, although two populations of differing degradation rates were not resolvable, a similar log-linear relationship between fluence rate and amount remaining after a standard light treatment was evident. Detailed kinetic analyses were not performed with peas and oats, but comparisons of low and high fluence rates demonstrated that photoprotection was similarly effective in these species. In Amaranthus, transfer from high to low fluence rate was accompanied by a rapid increase in degradation rate, indicating that the retarding effect of high-fluence-rate light is not a consequence of the disablement of the degradative machinery.
Immunochemical analyses confirmed the existence of photoprotection in all four species, and allowed the extension of the observations to periods of light treatment during which substantial chlorophyll production occurred. Considerable photoprotection was observed in oat seedlings exposed to summer sunlight. These results are interpreted in terms of the accumulation under high fluence rates of photoconversion intermediates not available to the degradative machinery which is specific for the far-red-absorbing form of phytochrome.
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Abbreviations
- Pfr:
-
far-red absorbing form of phytochrome
- Po:
-
amount of phytochrome measured at time zero
- Pt:
-
amount of phytochrome measured at time t
- Ptot:
-
total phytochrome
- WL:
-
white light
References
Abe, H., Yamamoto, K.T., Nagatani, A., Furuya, M. (1985) Characterization of green tissue-specific phytochrome isolated immunochemically from pea seedlings. Plant Cell Physiol. 26, 1387–1399
Bliss, D., Smith, H. (1986) Penetration of light into soil and its role in the control of seed germination. Plant Cell Environ. 8, 475–483
Brockmann, J., Schäfer, E. (1982) Analysis of Pfr destruction in Amaranthus caudatus L. — evidence for two pools of phytochrome. Photochem. Photobiol. 35, 555–558
Butler, W.L., Lane, H.C. (1965) Dark transformations of phytochrome in vivo. II. Plant Physiol. 40, 13–17
Fukshansky, L., Schäfer, E. (1983) Models in photomorphogenesis. In: Encyclopaedia of plant physiology N.S., vol. 16A: Photomorphogenesis, pp. 69–95, Shropshire, W., Jr., Mohr, E., eds. Springer, Berlin
Heim, B., Jabben, M., Schäfer, E. (1981) Phytochrome destruction in dark- and light-grown Amaranthus caudatus seedlings. Photochem. Photobiol. 34, 89–93
Kendrick, R.E., Frankland, B. (1968) Kinetics of phytochrome decay in Amaranthus seedlings. Planta 82, 317–320
Kendrick, R.E., Spruit, C.J.P. (1972) Light maintains high levels of phytochrome intermediates. Nature 237, 281–282
Kendrick, R.E., Spruit, C.J.P. (1973) Phytochrome intermediates in vivo. I. Effects of temperature, light intensity, wave-length, and oxygen on intermediate accumulation. Photochem. Photobiol. 18, 1349–144
Kendrick, R.E., Spruit, C.J.P. (1977) Phototransformations of phytochrome. Photochem. Photobiol. 26, 201–204
Mandoli, D.F., Waldron, L., Nemson, J.A., Briggs, W.R. (1982) Soil light transmission: implications for phytochrome-mediated responses. Carnegie Instn. Washington Yearb. 81, 32–34
McCurdy, D.W., Pratt, L.H. (1986a) Kinetics of intracellular redistribution of phytochrome in Avena coleoptiles after its conversion to the active, far-red-absorbing form. Planta 167, 330–336
McCurdy, D.W., Pratt, L.H. (1986b) Immunogold electron microscopy of phytochrome in Avena: Identification of intracellular sites responsible for phytochrome sequestering and enhanced pelletability. J. Cell Biol. 103, 2541–2550
Speth, V., Otto, V., Schäfer, E. (1986) Intracellular localisation of phytochrome in oat coleoptiles by electron microscopy. Planta 168, 299–304
Rüdiger, W. (1980) Phytochrome, a light receptor of photomorphogenesis. In: Structure and bonding, vol. 40, pp. 101–140, Hemmerich, P., ed. Springer, Berlin
Shimazaki, Y., Pratt, L.H. (1985) Immunochemical detection with rabbit polyclonal and mouse monoclonal antibodies of different pools of phytochrome from etiolated and green Avena shoots. Planta 164, 333–344
Tester, M., Morris, C. (1987) The penetration of light through soil. Plant Cell Environ. 10, 281–286
Tokuhisa, J.G., Daniels, S.M., Quail, P.H. (1985) Phytochrome in green tissue: Spectral and immunochemical evidence for two distinct molecular species of phytochrome in light-grown Avena sativa. Planta 164, 321–332
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Smith, H., Jackson, G.M. & Whitelam, G.C. Photoprotection of phytochrome. Planta 175, 471–477 (1988). https://doi.org/10.1007/BF00393067
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DOI: https://doi.org/10.1007/BF00393067